The invention relates to a manual torque adjuster for a motor vehicle steering system, having an electric motor (1), which has a pinion which is arranged on a motor shaft (6) on the output side of said electric motor (1), which pinion drives a belt pulley (3) via a toothed belt (2), and having a sensor unit (20), which is suitable for sensing the position of the motor and which is connected to an electronic controller which controls the electric motor (1), characterized in that the sensor unit (20) is arranged near to the output-side end of the motor shaft (6).
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1. A manual torque adjuster in a motor vehicle steering system, including:
an electric motor having a pinion arranged on a motor shaft on an output side of said electric motor,
a belt pulley coupled to transmit torque to a steering shaft physically coupled to a steering wheel of the steering system,
a toothed belt, wherein the pinion is configured to drive the belt pulley via the toothed belt,
a mounting block attached to an output-side bearing bracket of the electric motor which extends beyond a free end of the motor shaft,
a sensor unit placed on, and attached to, the mounting block and configured to sense a position of the motor, the sensing unit being connected to an electronic controller that controls the electric motor, and at least one magnet attached to the output-side end of the motor shaft, wherein the at least one magnet is arranged so that a magnetic field of the at least one magnet is detectable by the sensor unit.
6. A manual torque adjuster in a motor vehicle steering system, including:
an electric motor having a pinion arranged on a motor shaft on an output side of said electric motor,
a belt pulley coupled to transmit torque to a steering shaft physically coupled to a steering wheel of the steering system,
a toothed belt, wherein the pinion is configured to drive the belt pulley via the toothed belt,
a mounting block attached to an output-side bearing bracket of the electric motor which extends beyond a free end of the motor shaft,
a sensor unit placed on, and attached to, the mounting block and configured to sense a position of the motor, the sensing unit being connected to an electronic controller that controls the electric motor,
and an output-side bearing bracket of the electric motor, wherein the output-side bearing bracket of the electric motor is attached to a housing part using screws, which housing part is provided with elongated holes configured to enable belt tensioning.
2. The manual torque adjuster according to
3. The manual torque adjuster according to
4. The manual torque adjuster according to
5. The manual torque adjuster according to
7. The manual torque adjuster according to
8. The manual torque adjuster according to
9. The manual torque adjuster according to
10. The manual torque adjuster according to
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This application is a National Stage of PCT International Application No. PCT/EP2011/006180, filed on Dec. 8, 2011, and claims priority of German Patent Application No. 10 2010 054 135.4, filed on Dec. 10, 2010. The disclosures of the aforementioned applications are incorporated herein in their entirety by reference.
The present invention relates to a manual torque adjuster.
The use of steering systems without a direct mechanical coupling between the steering wheel and the steering gear in motor vehicles is known. Such steering systems are referred to as steer-by-wire steering systems (SbW steering systems). It is necessary in such systems to transmit torques, which correspond to the driving feel of a conventional steering system, to the driver via the steering wheel. Said torques are, for example, torques of inertia and return torques which originate from driving surface influences and steering kinematics. If it is not possible to sense such torques on the steering wheel, safe driving of the motor vehicle by the driver is difficult.
Manual torque adjusters come in various types. It is known in the case of such actuators from U.S. Pat. No. 6,820,713 B2, to create a particularly compact design of the upper steering shaft connected to the steering wheel in an axial direction wherein the required electric motor is arranged axially parallel next to the steering shaft and is coupled to the steering shaft via a belt drive. The electric motor does not extend beyond the length of the steering shaft.
Essential for the acceptance of such steering systems is an extremely precise regulation of the electric motor which generates the manual torque. It is necessary for such regulation to provide the electric motor with a motor position sensor which indicates the current position and, where appropriate, also the angle of rotation speed and direction of the rotor. In known manual torque adjusters, said sensor sits on the free end of the motor shaft which is opposite the output side.
The associated electronics are generally also arranged on the side facing away from the output side of the electric motor. Thus the configuration of the electric motor is extended in an axial direction which is undesirable in particularly compact arrangements. In particular the arrangement of the motor position sensor, also defines the position of the electronic control unit (ECU) of the manual torque adjuster within narrow limits since efforts are made to keep the electric cables between the sensor and the ECU short.
Proceeding from said prior art, the problem to be solved by the present invention is to provide a manual torque adjuster for a SbW steering system which is particularly short in an axial direction.
This problem may be solved by a manual torque adjuster having various features, e.g., as may be recited in one or more of the attached claims.
Because the motor position sensor is arranged on the output side of the shaft end, the electric motor can directly round off the bearing of the motor shaft with its motor housing on the side opposite the output side. A requirement for space is indicated by the necessary mechanical force transmission elements on the output side or gear end of the electric motor; said space is not exploited fully by the mechanical components. If the motor position sensor is arranged in said region, then this part of the space available is used more effectively.
It is advantageous if the output side of the electric motor is provided with a pinion, for example, a toothed belt pinion, and the shaft end of the motor shaft supports a permanent magnet arrangement because the magnetic field rotating during operation can then be detected easily.
If a mounting block is also attached to the pinion-side bearing bracket of the electric motor, which extends beyond the free end of the motor shaft, the motor position sensor can be attached to said mounting block. It is advantageous here if the mounting block is located in the region around which the toothed belt loops. This embodiment makes it possible to fit the mounting block onto the bearing bracket before the toothed belt is fitted.
It is also advantageous if the motor position sensor is connected to an electronic controller ECU via electric cables, where said controller is arranged on the side of the toothed belt opposite the motor because the motor position sensor, the electric connection and the ECU are then located outside the field of interference of the electric motor. In a conventional arrangement of the motor position sensor on the opposite shaft end, a positioning of the ECU in the region of the belt drive or at the distance from the electric motor would require the connection cables between the motor position sensor and the ECU to lead out of the electric motor and, where possible, run parallel to the motor housing. This would have an undesirable effect on the signal from the motor position sensor.
The mounting block preferably has a base which is attached to the bearing bracket of the electric motor and which extends parallel to and at a distance from the motor pinion, as well as an annular region which partially encloses the motor pinion and which surrounds the outside of the magnet arrangement on the front side of the motor shaft. A positioning aid for the motor position sensor, for example in the form of alignment pins which enable the custom fitting of the sensor, can be provided in this annular region.
Finally, it is an advantage if the motor is attached using screws in the region of the output side of its bearing bracket to a housing part which is provided with elongated holes in this region. The motor can then be positioned when fitting in such a way that the toothed belt is tensioned in the manner intended. This is facilitated or actually made possible in the present case through the arrangement of the motor position sensor as per the invention because the motor position sensor can be connected to the ECU at the defined fitting position using short cables, said ECU being connected to the drive housing separately from the motor. The positioning of the motor for tensioning the toothed belt then effects a displacement of the motor position sensor, but not the ECU. The number of components to be moved for belt tensioning is thus minimised. This reduces the available space to be provided for the manual torque adjuster and improves the packaging.
Embodiments of the present invention are described in greater detail below on the basis of the drawings.
The break through 5 in the plate 4 encloses the region of the bearing of the shaft 6 and also extends in the direction of the region around which the toothed belt 2 loops. A mounting block 8 is arranged in said region which is not visible in
One of the three attachment screws 7 for fixing the electric motor 1 to the plate 4 has been removed in the diagram in
The sensor unit 20 is connected to an ECU that is not shown via a plurality of electric cables 26. It can be arranged above the belt drive, for example, on the side opposite the electric motor 1 and consequently is located outside the field of interference of the electric motor 1.
The electric cables 26 are connected to a plug that is not shown. The diagram according to
It can also be seen from
Galehr, Robert, Scholten, Michael
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Dec 08 2011 | THYSSENKRUPP PRESTA AG | (assignment on the face of the patent) | / | |||
Apr 24 2013 | SCHOLTEN, MICHAEL | THYSSENKRUPP PRESTA AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 030374 | /0261 | |
Apr 24 2013 | GALEHR, ROBERT | THYSSENKRUPP PRESTA AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 030374 | /0261 |
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